CN103078678A - Satellite-borne laser wireless energy transmission system - Google Patents
Satellite-borne laser wireless energy transmission system Download PDFInfo
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Abstract
The invention discloses a satellite-borne laser wireless energy transmission system, which comprises a wireless laser energy emitting machine and a wireless laser energy receiving machine, wherein the wireless laser energy emitting machine and the wireless laser energy receiving machine are respectively arranged on an energy sending spacecraft and an energy receiving spacecraft. The system provided by the invention can be used for carrying out wireless energy transmission between satellites or modular spacecrafts, the spacecraft energy obtaining resources can be enhanced, the service life of the spacecraft can be prolonged, the space resource utilization rate is improved, and meanwhile, power transmission for space vehicles and the like can be realized.
Description
Technical field
The present invention relates to precise light electronic product practical technique field, relate in particular to a kind of satellite borne laser wireless energy transfer system.
Background technology
Distributed restructural satellite system is a kind of spacecraft architecture that faces the future, by a plurality of basic compositions unit namely " module spacecraft " form, its be in essence task function differentiation, separate and interconnect, each module spacecraft can rapid batch manufacturing and independent transmission, connect and wireless energy transfer by wireless data in the time of in orbit, consist of the virtual spacecraft of a telotism.Wireless energy transfer namely becomes the key means of Power supply between the module aircraft, reaches the purpose of each module energy supply Focus with it.
When the module spacecraft is under shadow surface, the emergency rating or battery electric quantity deficiency and module spacecraft are under the state of battery electric quantity deficiency, need to obtain energy by external means.In order to satisfy higher efficiency of transmission and the instructions for use of space environment, need to carry out the overall design technique of laser radio energy transmission system, structure is suitable for the energy transmission system that use in the space, and system is carried out the decomposition of efficiency of transmission, links is optimized design, select efficient device, reach the high-transmission efficient of system.
Summary of the invention
The invention provides a kind of satellite borne laser wireless energy transfer system, can carry out between the satellite or the wireless energy transfer between the module spacecraft, not only can increase aircraft energy harvesting source, prolong aircraft useful life, increasing also can be space delivery vehicle transmission of electricity etc. simultaneously to the utilance of space resources.
The objective of the invention is to be achieved through the following technical solutions:
This satellite borne laser wireless energy transfer system comprises wireless laser energy transmitter and wireless laser energy receiver;
Wireless laser energy transmitter is by laser (1), transmitting terminal controller (2), transmitting optics antenna (3), transmitting terminal two dimension turntable (4) forms, wherein laser (1) links to each other by optical fiber with transmitting optics antenna (3), transmitting terminal controller (2) and transmitting terminal two dimension turntable (4), transmitting optics antenna (3), laser (1) all links to each other by cable, the transmitting terminal controller provides power supply and control signal for two-dimentional turntable, transmitting optics antenna (3) is arranged on by being spirally connected on the transmitting terminal two dimension turntable (4), motion by transmitting terminal two dimension turntable drives the transmitting optics antenna movement, realizes aiming at; Be provided with non-spherical lens in transmitting optics antenna (3), the exit end of optical fiber is arranged on the focus of non-spherical lens; Also be provided with ccd detector and line source reflector in the transmitting optics antenna (3), the optical axis of the two is all parallel with the optical axis of non-spherical lens;
Wireless laser energy receiver forms by receiving optical antenna (6), receiving terminal two dimension turntable (7) and energy management system (8), wherein receiving terminal controller (5) links to each other by cable with receiving terminal two dimension turntable (7), reception optical antenna (6), receive optical antenna (6) and link to each other by cable with energy management system (8), receive optical antenna (6) and be arranged on by being spirally connected on the receiving terminal two dimension turntable (7); Receive in the optical antenna (6) and be provided with spherical mirror and in the focal plane of described spherical mirror optical-electrical converter be installed; Receive on the receiving plane in the optical antenna and also be provided with the corner reflection prism;
Wireless laser energy transmitter and wireless laser energy receiver are installed in respectively energy and send on spacecraft and the energy reception spacecraft;
Described transmitting terminal controller carries out following operation:
(1) receives the posture information of two spacecrafts that Star Service sends, calculate wireless laser energy transmitter optical axis information relative to wireless laser energy receiver, start transmitting terminal two dimension turntable, centered by wireless laser energy transmitter and the relative optical axis of wireless laser energy receiver, determine scanning area, start acquisition mode;
(2) the line source reflector that starts in the transmitting optics antenna sends line source, regulates transmitting terminal two dimension turntable and carries out pitching, azimuth scan namely centered by transmitting terminal optical axis relative to receiving terminal in scanning area, carries out helical scanning;
(3) judge the transmitting optics antenna ccd detector as the light source image that whether has the corner reflection prism to return in the plane, if having then the end of scan, enter smart tracking mode; If the light source image that does not return, then circulation step (3) is proceeded scanning;
(4) enter smart tracking mode after, regulate two-dimentional turntable, light source image is finely tuned, make light source image adjust to the picture centre of ccd detector, the locking transmit direction;
(5) behind the locking transmit direction, open laser, the laser beam of laser is sent to the transmitting optics antenna by optical fiber, behind the non-spherical lens compression collimation that arranges by the transmitting optics antenna, the laser beam of laser is launched;
Described receiving terminal controller carries out following operation:
The posture information of two spacecrafts that the reception Star Service is sent, calculate wireless laser energy transmitter optical axis information relative to wireless laser energy receiver, start receiving terminal two dimension turntable, order receives optical antenna and points to described relative optical axis, receiving optical antenna converges to laser beam on the optical-electrical converter by spherical lens, send into energy management system after finishing opto-electronic conversion, directly power to spaceborne battery charging and discharging or to load, finish the wireless transmission of energy.
Described optical-electrical converter adopts the GaAs solar cell material.
Described non-spherical lens is plating anti-reflection film non-spherical lens.
Described spherical lens is plating anti-reflection film spherical lens.
Beneficial effect of the present invention:
1) namely adopts line source, prism of corner cube and CCD imaging by the position deviation detection method and with the picture centre of Image Adjusting to ccd detector, can guarantee the position detection accuracy at Laser emission, reception two ends; And can carry out the angle adjustment in pitching, orientation by two-dimentional turntable, control laser beam transmit direction reaches higher efficiency of transmission.
2) transmitting terminal adopts non-spherical lens to carry out laser beam compression collimation, satisfies longer-distance transmission requirement; And by the plating anti-reflection film prevent the decay.Receiving terminal adopts spherical lens that the laser beam that receives is focused on, and makes the relative concentrated area of energy carry out the photoelectricity dress and changes, and prevent decay by the plating anti-reflection film.
3) by adopting the efficient photoelectricity treater transducer, be electric energy with the transform light energy of inputting, realize photovoltaic energy conversion, guarantee higher electro-optical efficiency.
4) this satellite borne laser wireless energy transfer system is applied on the wireless energy transfer between the module spacecraft, efficiency of transmission is high, equipment is light, can satisfy the radio energy-transmitting requirement under the dynamic environment, the development of this equipment, the energy-provision way of energy Effective Raise spacecraft is with a wide range of applications.
Description of drawings
Fig. 1-satellite-carried wireless laser energy transmission system pie graph;
Fig. 2-transmitting optics antenna schematic diagram;
Fig. 3-reception optical antenna schematic diagram;
Fig. 4-satellite-carried wireless laser energy transmission system workflow diagram;
1-laser, 2-transmitting terminal controller, 3-transmitting antenna, 4-transmitting terminal two dimension turntable, 5-transmitting terminal controller, 6-reception antenna, 7-receiving terminal two dimension turntable, 8-optical-electrical converter;
Embodiment
In order to understand better technical scheme of the present invention, below in conjunction with drawings and the specific embodiments the present invention is done to describe in further detail.
This satellite borne laser wireless energy transfer system comprises wireless laser energy transmitter and wireless laser energy receiver;
Wireless laser energy transmitter is comprised of laser 1, transmitting terminal controller 2, transmitting optics antenna 3, transmitting terminal two dimension turntable 4, wherein laser 1 and transmitting optics antenna 3 link to each other by optical fiber, transmitting terminal controller 2 all links to each other by cable with transmitting terminal two dimension turntable 4, transmitting optics antenna 3, laser, the transmitting terminal controller provides power supply and control signal for two-dimentional turntable, transmitting optics antenna 3 is arranged on by being spirally connected on the transmitting terminal two dimension turntable 4, motion by transmitting terminal two dimension turntable drives the transmitting optics antenna movement, realizes aiming at; Be provided with non-spherical lens in transmitting optics antenna 3, the exit end of optical fiber is arranged on the focus of non-spherical lens; Also be provided with ccd detector and line source reflector in the transmitting optics antenna 3, the two is all parallel with the optical axis of non-spherical lens;
Wireless laser energy receiver forms by receiving optical antenna 6, receiving terminal two dimension turntable 7 and energy management system 8, wherein receiving terminal controller 5 links to each other by cable with receiving terminal two dimension turntable 7, reception optical antenna (6), receive optical antenna 6 and energy management system 8 and link to each other by cable, receive optical antenna 6 and be arranged on by being spirally connected on the two-dimentional turntable 7 of receiving terminal; Receive in the optical antenna 6 and be provided with spherical mirror and in the focal plane of described spherical mirror optical-electrical converter be installed; Receive on the receiving plane in the optical antenna and also be provided with the corner reflection prism;
Wireless laser energy transmitter and wireless laser energy receiver are installed in respectively energy and send on spacecraft and the energy reception spacecraft, carry out energy transmission by space link to wireless laser energy receiver by wireless laser energy transmitter; System forms as shown in Figure 1.
As shown in Figure 4, the specific works flow process of this system is:
(1) when receiving spacecraft, energy detects satellite power supply when not enough by self energy management system, if need to carry out the wirelessly provisioning energy, then by the spacecraft wireless communication system energy transmission request is sent to energy and send spacecraft, starting device work; If do not need to carry out the wirelessly provisioning energy, then energy receives spacecraft by the energy management system detection satellite power supply of self;
(2) the energy transmitting terminal controller that sends spacecraft receives the posture information of two spacecrafts that energy transmission request and Star Service send, after matrixing, obtain wireless laser energy transmitter optical axis information relative to wireless laser energy receiver, start transmitting terminal two dimension turntable, centered by wireless laser energy transmitter and the relative optical axis of wireless laser energy receiver, determine scanning area, start acquisition mode;
The posture information of two spacecrafts that the receiving terminal controller reception Star Service of energy reception spacecraft is sent calculates wireless laser energy transmitter optical axis information relative to wireless laser energy receiver, starts receiving terminal two dimension turntable, points to relative optical axis;
(3) the line source reflector that starts in the transmitting optics antenna of transmitting terminal controller sends line source, regulates transmitting terminal two dimension turntable and carries out pitching, azimuth scan namely centered by transmitting terminal optical axis relative to receiving terminal in scanning area, carries out helical scanning; Line source is sent to the corner reflection prism, corner reflection prism back light source images;
(4) the transmitting terminal controller judge the transmitting optics antenna ccd detector as the light source image that whether has the corner reflection prism to return in the plane, if having then the end of scan, enter smart tracking mode; If the light source image that does not return, then circulation step (3) is proceeded scanning;
(5) after the transmitting terminal controller captures light source image and enters smart tracking mode, regulate two-dimentional turntable by the transmitting terminal controller, light source image is finely tuned, make light source image adjust to the picture centre of ccd detector, the locking transmit direction;
(6) behind transmitting terminal controller locking transmit direction, open laser, the laser beam of laser is sent to transmitting antenna by optical fiber, behind the inner non-spherical lens compression collimation that arranges of transmitting antenna, the laser beam of laser is launched; Receive optical antenna and by spherical lens laser beam is converged on the optical-electrical converter, send into energy management system after finishing opto-electronic conversion, directly power to spaceborne battery charging or to load, finish the wireless transmission of energy;
(7) energy receives the energy management system detection satellite power supply state of spacecraft, judges whether to charge complete, if it is finishes Energy Transfer, otherwise continues power supply.
Laser is connected with the transmitting optics antenna by optical fiber in wireless laser energy transmitter, the laser electric light is converted to laser beam is sent to the transmitting optics antenna.And the transmitting terminal controller connects by cable with transmitting terminal two dimension turntable, for two-dimentional turntable provides power supply and control signal, the transmitting optics antenna is fixed on by being spirally connected on the two-dimentional turntable, by the motion drive transmitting optics antenna movement of two-dimentional turntable, realizes aiming at.
In wireless laser energy receiver, receive optical antenna and be installed in by being spirally connected on the two-dimentional turntable, the motion drive reception optical antenna motion by receiving terminal two dimension turntable realizes two-way aligning.Receive the electric energy of optical antenna after with opto-electronic conversion and send into energy management system, carry out power conversion and battery is carried out management of charging and discharging, and can drive loaded work piece.And the control of receiving terminal two dimension turntable is also finished by cable by the receiving terminal controller.
Laser of the present invention adopted have high electrical-optical conversion efficiency, volume is little, lightweight, semiconductor laser cheaply, satisfy the laser about solar cell absworption peak 800nm, for satisfying high-power requirement, adopted the integrated high-power semiconductor laser array of coupling fiber output, adopt the laser constant-flow driver of BUCK voltage-dropping type structure, can efficiently carry out the electric light conversion, be met necessarily required laser beam.Poor for semiconductor laser beam quality, radiation intensity, be not suitable for the situation of long-distance transmissions, adopted the transmitting optics antenna that laser beam is compressed collimation, and then launch, as shown in Figure 2, by non-spherical lens, and behind the plating anti-reflection film, can make beam shaping reach the less angle of divergence.
The laser that sends from wireless laser energy transmitter arrives when receiving optical antenna through the space transmission, its hot spot is expanded, the photosurface of optical-electrical converter is very little again, and the present invention adopts the reception optical antenna that laser energy is converged on the photosurface of photovoltaic power converter.Receive optical antenna and adopt a spherical lens, laser beam can be focused on, and plate anti-reflection film at spherical lens and prevent decay; As shown in Figure 3.And optical-electrical converter is installed on the focal plane, and the laser beam after the focusing carries out the photoelectricity dress with the relative concentrated area of energy and changes.Optical-electrical converter adopts the GaAs solar cell material, has at present the highest photovoltaic energy conversion efficient.Solar cell is close in the copper substrate, by cooling piece the heat that solar cell in the copper substrate produces is led away again, and fan and fin play the effect of auxiliary heat dissipation.
Under space environment, carry out wireless energy transfer between the spacecraft, need to overcome the difficulty that spacecraft carries out relative motion simultaneously, the present invention has adopted automatically with the mode of taking aim at aligning, transmitting optics antenna and reception optical antenna all are installed on the two-dimentional turntable, by the motion of two-dimentional turntable at pitching, azimuth direction, two optical axis of antennas are aimed at, reduced the link loss of laser transmission, reach higher efficiency of transmission.Control system in the controller can the driving moment motor, optical antenna is finished in the space catch, the motion control arithmetic such as essence trackings, reaches the purpose of aligning, tracking.The detection of location status is finished by line source, prism of corner cube and ccd detector between transmitting optics antenna and the reception optical antenna, line source is launched a low-power laser bundle, reflected by prism of corner cube, imaging on CCD, by detecting the position of pixel, obtain position deviation, carry out closed-loop control by motion control unit.And the information interaction at sending and receiving two ends via satellite communication system finish.
By the enforcement of the technical program, reached following effect:
A. adopt large power semiconductor laser array to carry out the electric light conversion, can obtain laser beam efficient, powerful 800nm, satisfy the requirement of solar cell absworption peak.Adopt non-spherical lens to carry out laser beam compression collimation, laser beam divergence reaches 1mrad, can satisfy longer-distance transmission requirement.And spherical lens plate anti-reflection film prevent the decay;
B. adopt the GaAs solar cell material as optical-electrical converter, guarantee higher photoelectric conversion efficiency, adopt spherical lens that the laser beam that receives is focused on, make the relative concentrated area of energy carry out the photoelectricity dress and change, reduce the efficiency losses that solar panel mode gap causes.
C. adopt the automatic aiming tracking system, solve and to have under the relative motion state feasibility problem of wireless energy transfer between spacecraft, positioning precision reduces the link loss of laser transfer less than 100um.
D. namely adopt line source, prism of corner cube and CCD imaging by the position deviation detection method and with Image Adjusting to the picture centre of ccd detector, can guarantee the position detection accuracy at Laser emission, reception two ends, adopt position scanning, essence to follow the tracks of the switching of two kinds of control models, satisfy the ability of rapidity, accuracy and the Adaptive change of laser link foundation.
E. by this scheme, both satisfied the instructions for use of space environment, and guaranteed again higher efficiency of transmission, final electricity-electrical transfer efficiency can reach more than 15%, and compact conformation, takies less installing space.
In sum, above is preferred embodiment of the present invention only, is not for limiting protection scope of the present invention.Within the spirit and principles in the present invention all, any modification of doing, be equal to replacement, improvement etc., all should be included within protection scope of the present invention.
Claims (4)
1. the satellite borne laser wireless energy transfer system is characterized in that, this satellite borne laser wireless energy transfer system comprises wireless laser energy transmitter and wireless laser energy receiver;
Wireless laser energy transmitter is by laser (1), transmitting terminal controller (2), transmitting optics antenna (3), transmitting terminal two dimension turntable (4) forms, wherein laser (1) links to each other by optical fiber with transmitting optics antenna (3), transmitting terminal controller (2) and transmitting terminal two dimension turntable (4), transmitting optics antenna (3), laser (1) all links to each other by cable, the transmitting terminal controller provides power supply and control signal for two-dimentional turntable, transmitting optics antenna (3) is arranged on by being spirally connected on the transmitting terminal two dimension turntable (4), motion by transmitting terminal two dimension turntable drives the transmitting optics antenna movement, realizes aiming at; Be provided with non-spherical lens in transmitting optics antenna (3), the exit end of optical fiber is arranged on the focus of non-spherical lens; Also be provided with ccd detector and line source reflector in the transmitting optics antenna (3), the optical axis of the two is all parallel with the optical axis of non-spherical lens;
Wireless laser energy receiver forms by receiving optical antenna (6), receiving terminal two dimension turntable (7) and energy management system (8), wherein receiving terminal controller (5) links to each other by cable with receiving terminal two dimension turntable (7), reception optical antenna (6), receive optical antenna (6) and link to each other by cable with energy management system (8), receive optical antenna (6) and be arranged on by being spirally connected on the receiving terminal two dimension turntable (7); Receive in the optical antenna (6) and be provided with spherical mirror and in the focal plane of described spherical mirror optical-electrical converter be installed; Receive on the receiving plane in the optical antenna and also be provided with the corner reflection prism;
Wireless laser energy transmitter and wireless laser energy receiver are installed in respectively energy and send on spacecraft and the energy reception spacecraft;
Described transmitting terminal controller carries out following operation:
(1) receives the posture information of two spacecrafts that Star Service sends, calculate wireless laser energy transmitter optical axis information relative to wireless laser energy receiver, start transmitting terminal two dimension turntable, centered by wireless laser energy transmitter and the relative optical axis of wireless laser energy receiver, determine scanning area, start acquisition mode;
(2) the line source reflector that starts in the transmitting optics antenna sends line source, regulates transmitting terminal two dimension turntable and carries out pitching, azimuth scan namely centered by transmitting terminal optical axis relative to receiving terminal in scanning area, carries out helical scanning;
(3) judge the transmitting optics antenna ccd detector as the light source image that whether has the corner reflection prism to return in the plane, if having then the end of scan, enter smart tracking mode; If the light source image that does not return, then circulation step (3) is proceeded scanning;
(4) enter smart tracking mode after, regulate two-dimentional turntable, light source image is finely tuned, make light source image adjust to the picture centre of ccd detector, the locking transmit direction;
(5) behind the locking transmit direction, open laser, the laser beam of laser is sent to the transmitting optics antenna by optical fiber, behind the non-spherical lens compression collimation that arranges by the transmitting optics antenna, the laser beam of laser is launched;
Described receiving terminal controller carries out following operation:
The posture information of two spacecrafts that the reception Star Service is sent, calculate wireless laser energy transmitter optical axis information relative to wireless laser energy receiver, start receiving terminal two dimension turntable, order receives optical antenna and points to described relative optical axis, receiving optical antenna converges to laser beam on the optical-electrical converter by spherical lens, send into energy management system after finishing opto-electronic conversion, directly power to spaceborne battery charging and discharging or to load, finish the wireless transmission of energy.
2. satellite borne laser wireless energy transfer system as claimed in claim 1 is characterized in that, described optical-electrical converter adopts the GaAs solar cell material.
3. satellite borne laser wireless energy transfer system as claimed in claim 1 is characterized in that, described non-spherical lens is plating anti-reflection film non-spherical lens.
4. satellite borne laser wireless energy transfer system as claimed in claim 1 is characterized in that, described spherical lens is plating anti-reflection film spherical lens.
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石德乐: "激光无线能量传输机理分析及仿真", 《空间电子技术》 * |
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